Cogeneration and Polygeneration Systems

Cogeneration and Polygeneration Systems is a book that explores state-of-the-art modeling, design, analysis, and optimization procedures for creating and retooling optimally efficient combined heat and power (CHP) and polygeneration energy systems. It adopts exergetic and thermoeconomic analysis and related modeling and simulation tools to inform performance and systems design in modern cogeneration plants.

Format: Paperback / softback
Length: 406 pages
Publication date: 06 November 2020
Publisher: Elsevier Science Publishing Co Inc

Cogeneration and Polygeneration Systems delve into a comprehensive suite of advanced modeling, design, analysis, and optimization techniques to create and revamp highly efficient combined heat and power (CHP) and polygeneration energy systems. This book employs exergetic and thermoeconomic analysis, along with related modeling and simulation tools, to provide insights into performance and systems design in modern cogeneration plants. The chapters offer a systematic approach to designing, operating, and troubleshooting cogeneration systems when integrated with industrial processes. Thorough coverage is provided on cogeneration targets, environmental impacts, total site integration, availability and reliability issues.

CHP systems, also known as combined heat and power systems, are energy-efficient systems that generate both heat and power from a single source. They are commonly used in industries, commercial buildings, and residential complexes to reduce energy consumption and greenhouse gas emissions. Polygeneration systems, on the other hand, go beyond CHP by generating multiple forms of energy, such as electricity, heat, cooling, and steam, from a single source. These systems are more versatile and can be used in a wider range of applications, including power generation, district heating, and industrial processes.

The book begins by introducing the fundamentals of CHP and polygeneration systems, including their components, operating principles, and benefits. It then discusses the various modeling and simulation tools used in these systems, such as exergetic analysis, thermoeconomic analysis, and process simulation. The authors provide detailed examples and case studies to illustrate the application of these tools in real-world scenarios.

Chapters 2 to 5 cover the design, operation, and troubleshooting of CHP systems. The authors discuss the factors that influence the design of CHP systems, such as fuel selection, heat exchanger design, and control strategies. They also provide guidelines for optimizing the performance of CHP systems through load management, energy storage, and renewable energy integration.

Chapter 6 focuses on polygeneration systems, including their components, operating principles, and applications. The authors discuss the different types of polygeneration systems, such as combined cooling, heating, and power (CCHP), trigeneration, and quaternary generation, and their respective advantages and disadvantages. They also provide examples of polygeneration systems in different industries and discuss the challenges associated with their implementation.

Chapter 7 explores the environmental impacts of CHP and polygeneration systems. The authors discuss the potential benefits of these systems in reducing greenhouse gas emissions, improving air quality, and reducing energy consumption. They also address the challenges associated with implementing these systems, such as regulatory requirements, public perception, and infrastructure costs.

Chapter 8 discusses the total site integration of CHP and polygeneration systems. The authors discuss the benefits of integrating these systems with other energy sources, such as renewable energy sources and energy storage systems, to create a more sustainable and resilient energy system. They also provide examples of successful total site integration projects and discuss the challenges associated with integrating these systems with existing infrastructure.

Chapter 9 addresses the availability and reliability issues of CHP and polygeneration systems. The authors discuss the factors
The availability and reliability issues of CHP and polygeneration systems. The authors discuss the factors that influence the availability and reliability of these systems, such as equipment failure, maintenance, and operation. They also provide guidelines provide examples of successful strategies for improving the availability and reliability of CHP and polygeneration systems, such as predictive maintenance, fault tolerance, and system redundancy.

In conclusion, Cogeneration and Polygeneration Systems is a comprehensive and practical guide
In conclusion, Cogeneration and Polygeneration Systems is a comprehensive and practical guide for professionals and researchers involved in the design, operation, and optimization of CHP and polygeneration energy systems. The book energy systems. The book adopts a multidisciplinary approach, combining exergetic and thermoeconomic analysis, related modeling and simulation tools, and real-world examples to provide a comprehensive understanding of these systems. The chapters offer a systematic approach to designing, operating, and troubleshooting cogeneration systems when integrated with industrial processes, addressing key topics such as cogeneration targets, environmental impacts, total site integration, availability and reliability issues. The book is well-organized, with each chapter providing a clear overview of the topic and referencing relevant literature for further reading. Overall, Cogeneration and Polygeneration Systems is a valuable resource for anyone seeking to advance their knowledge and expertise in the field of CHP and polygeneration energy systems.

Weight: 832g
Dimension: 234 x 190 x 25 (mm)
ISBN-13: 9780128172490